Communication method, method for forwarding data message during the communication process and communication node thereof

ABSTRACT

The present invention provides a communication method, and a method for forwarding a data message during the communication process and a communication node. Wherein, the configuration mode for identity recognition is clarified, and under the architecture based on access identifier and location separation in the network, a specific method for implementing identity recognition is provided, and the processing performed by each network element is regulated; the requirement for the number of the coding spaces is met, meanwhile the present invention realizes the intercommunication and interconnection with the legacy IP network, realizes the compatibility with the upper application programs of IPv4/IPv6, and supports the various application programs of the IPv4/IPv6 network to transplant smoothly to the architecture based on access identifier and location separation in the network.

TECHNICAL FIELD

The present invention relates to the field of communication technology,and in particular, to a communication method, a method for forwarding adata message during the communication process and a communication node.

BACKGROUND ART

The IP address has dual functions in TCP/IP (Transmission ControlProtocol/Internet Protocol) widely used in the existing Internet, i.e.,the IP address serves not only as the location identifier of the hostnetwork interface of the communication terminal of the network layer inthe network topology, but also as the access identifier of the hostnetwork interface of the transmission layer. The case of host mobilitywas not taken into consideration when the TCP/IP protocol was initiallydesigned. However, as host mobility becomes more and more popular, thedefect of semantics overload of this kind of IP address becomes more andmore apparent. When the IP address of a host changes, not only theroute, but also the access identifier of the communication terminal hostchanges, which will result in bigger and bigger load of the route, andthe change of the host identifier will cause interruption of applicationand connection. The access identifier and location separation problem isproposed to aim to solve the problems of semantics overload of the IPaddress, severe load of the route and so on, separate the dual functionsof the IP address, realize support for problems including mobility,multi-homeness, dynamic redistribution of IP addresses, reduction ofroute load, and inter-visit between different network areas in the nextgeneration of internet.

In the prior art, the implementing method based on a network router isone of the solutions about access identifier and location separation.

In the prior art, the format of the host identifier is the IPV4 address,and the access identifier compatible with the upper-layer applicationcan be only in IPV4 format. As the popularity and development of IPapplication, the IPV4 address space cannot meet the requirement for thenumber by the service applications any more. In the prior art, some newmethods for implementing the access identifier, for example, IPV6address, user identity recognition in HIP (Host Identity Protocol), aredefined. These methods are implemented by increasing the bit length ofthe identity recognition, and only consider how to expand the number ofname and address spaces. When the specific functions, like how to becompatible with the existing IPV4 and IPV6 terminals, how to becompatible with the upper-layer application, transplant of IPV4 and IPV6service application, are related, all of these need to be implemented byway of upgrading HOST software or modifying the service applicationprograms. The prior art realizes intercommunication with the IPV4terminal by way of supporting dual stack in the network or the terminal,and does not consider compatibility processing functions in access ofthe IPV4 terminal, transplant of IPV4 services and other aspects.

SUMMARY OF THE INVENTION

The technical problem to be solved in the present invention is toprovide a communication method, a method for forwarding a data messageduring the communication process and a communication node to meet therequirement for the number of the coding spaces and meanwhile realizeintercommunication between an access identifier and location separationnetwork and the legacy IP network.

In order to solve the above problem, the present invention provides acommunication method applied to an access identifier and locationseparation network, comprising:

an access service node establishing, for each accessed terminal, abinding relationship between a first identifier of the terminal and atransmitting-receiving link; and

when receiving a data message sent from the terminal on thetransmitting-receiving link, if a source address of the data message isa second identifier of the terminal, the access service node convertingthe source address to the first identifier of the terminal according tothe binding relationship and then sending the data message to a backbonenetwork for forwarding.

Preferably, the first identifier is an access identifier of theterminal, and the second identifier is a private network IP address ofthe terminal.

Preferably, the access identifier of the terminal comprises the privatenetwork IP address of the terminal, and prefix/suffix information.

Preferably, the access identifier of the terminal adopts an addresscoding format of IPV6.

Preferably, the prefix/suffix information is a constant or variabledetermined based on the access identifier and location separationnetwork.

Preferably, the transmitting-receiving link refers to: a point-to-pointconnection relationship established by the access service node for theterminal.

Preferably, the point-to-point connection relationship is a GeneralPacket Radio Service Tunneling Protocol (GTP) connection or apoint-to-point protocol (PPP) connection.

The present invention further discloses a communication method appliedto an access identifier and location separation network, comprises thefollowing steps of:

an access service node establishing and storing, for an accessedterminal, a corresponding relationship between a first identifier and asecond identifier of the terminal, and a binding relationship betweenthe first identifier and a transmitting-receiving link;

when receiving a data message whose destination address is the firstidentifier of the terminal, the access service node converting the firstidentifier to the second identifier according to the correspondingrelationship, and forwarding the converted data message to the terminalthrough the transmitting-receiving link corresponding to the firstidentifier according to the binding relationship.

Preferably, the first identifier is an access identifier of theterminal, and the second identifier is a private network IP address ofthe terminal.

Preferably, the access identifier of the terminal is composed of theprivate network IP address of the terminal and prefix/suffixinformation, and the prefix/suffix information is a constant or variabledetermined based on the access identifier and location separationnetwork, and/or, the access identifier of the terminal adopts an addresscoding format of IPV6.

Preferably, the transmitting-receiving link refers to a point-to-pointconnection relationship established by the access service node for theterminal, and the point-to-point connection relationship is a GeneralPacket Radio Service Tunneling Protocol (GTP) connection or apoint-to-point protocol (PPP) connection.

The present invention further provides a communication method applied toan access identifier and location separation architecture network,comprises the following steps of:

when an access service node to which a terminal accesses receives a datamessage sent from a correspondent node to the terminal, the accessservice node distributing a connection identifier to the correspondentnode of the terminal according to an access identifier of thecorrespondent node in a source address of the data message, and storinga corresponding relationship between the connection identifier and theaccess identifier of the correspondent node;

when the terminal communicates with the correspondent node through theconnection identifier, the access service node to which the terminalaccesses obtaining the access identifier of the correspondent nodeaccording to the corresponding relationship to determine thecorrespondent node, and realizing conversion between the accessidentifier of the correspondent node and the connection identifier.

Preferably, the connection identifier is a public network address or aprivate network address in a traditional communication network.

Preferably, the access service node distributes the same or differentconnection identifiers to the correspondent nodes of different accessedterminals.

The present invention further provides a communication method used forintercommunication between an access identifier and location separationnetwork and a legacy IP network, comprising the following steps of:

when receiving a data message sent from the access identifier andlocation separation network to the legacy IP network, anintercommunication node converting a first identifier of the datamessage to a corresponding second identifier and then sending the datamessage to the legacy IP network;

when receiving a data message sent from the legacy IP network to theaccess identifier and location separation network, theintercommunication node converting the second identifier in the datamessage to the corresponding first identifier and then sending the datamessage to the access identifier and location separation network.

Preferably, the first identifier is composed of a private network IPaddress of a terminal and prefix/suffix information, and the secondidentifier is a public network IP address.

Preferably, the first identifier is an access identifier of the terminalin the access identifier and location separation network.

The present invention further provides a communication method used forintercommunication between an access identifier and location separationnetwork and a legacy IP network, comprising the following steps of:

when a first terminal in the legacy IP network communicates with asecond terminal in the access identifier and location separationnetwork, an intercommunication node distributing to the second terminala connection identifier identifiable to the first terminal and storing acorresponding relationship between the connection identifier and anaccess identifier of the second terminal, and when the first terminalcommunicates with the second terminal through the connection identifier,the intercommunication node obtaining the access identifier of thesecond terminal according to the corresponding relationship to determinethe second terminal and realizing conversion between the accessidentifier and the connection identifier of the second terminal.

Preferably, the connection identifier is a public network IP address ora private network IP address in the legacy IP network.

Preferably, the access service node distributes the same or differentconnection identifiers to the second terminals communicating withdifferent first terminals.

The present invention further provides a method for forwarding a datamessage during a communication process applied to an access identifierand location separation network, comprising the following steps of:

when an access service node to which a terminal accesses receives a datamessage sent from a correspondent node to the terminal, the accessservice node distributing a connection identifier to the correspondentnode according to an access identifier of the correspondent node in asource address of the data message, and storing a correspondingrelationship between the connection identifier and the access identifierof the correspondent node;

the access service node to which the terminal accesses replacing thesource address in the data message with the connection identifier andthen sending the data message to the terminal;

after receiving the data message in which the source address is theconnection identifier, the terminal responding to the correspondent nodewith a data message using the connection identifier as a destinationaddress;

after receiving the data message with which the terminal responds, theaccess service node to which the terminal accesses searching for thestored corresponding relationship according to the connection identifierto obtain the access identifier of the correspondent node, and replacingthe destination address in the data message with the access identifierof the correspondent node and then forwarding the data message to anaccess node to which the correspondent node accesses.

The present invention further provides a method for forwarding a datamessage during a communication process applied to an access identifierand location separation network, comprising the following steps of:

an access service node to which a terminal accesses establishing apoint-to-point connection relationship for the terminal, and storing abinding relationship between the point-to-point connection relationshipand an access identifier of the terminal;

when the terminal sends a data message to a correspondent node throughthe point-to-point connection relationship, the access service node towhich the terminal accesses replacing a source address in the datamessage with the access identifier of the terminal according to thebinding relationship, and then sending the data message to an accessservice node where the correspondent node is located;

after receiving the data message, the access service node where thecorrespondent node is located distributing a connection identifier tothe terminal according to the access identifier of the terminal therein,and storing a corresponding relationship between the connectionidentifier and the access identifier of the terminal; then replacing thesource address in the data message with the connection identifier andthen sending the data message to the correspondent node;

the correspondent node responding with a data message using theconnection identifier as a destination address, and the access servicenode where the correspondent node is located replacing the destinationaddress in the data message with the access identifier of the terminalaccording to the stored corresponding relationship and then sending thedata message to the access service node where the terminal is located.

Preferably, the access identifier comprises a private network IP addresspart in a traditional communication network, and prefix/suffixinformation.

Preferably, the prefix/suffix information is a constant or variabledetermined based on the access identifier and location separationnetwork.

Preferably, the connection identifier adopts a public network IP addressor a private network IP address in the traditional communicationnetwork.

Preferably, the access service node distributes the same or differentconnection identifiers to the correspondent nodes of different accessedterminals.

The present invention further provides a communication method applied toan access identifier and location separation network, comprising thefollowing steps of:

a first access service node establishing a first point-to-pointconnection relationship and a second point-to-point connectionrelationship respectively for a first terminal and a second terminalthat have accessed, and storing binding relationships between thepoint-to-point connection relationships and access identifiers ofcorresponding terminals respectively;

when receiving a data message using the access identifier of the firstterminal as a destination address, the first access service nodedistributing a first connection identifier to an correspondent node ofthe first terminal according to the access identifier of thecorrespondent node in a source address in the data message, and storinga corresponding relationship between the first connection identifier andthe access identifier of the correspondent node; and

when receiving a data message using the access identifier of the secondterminal as a destination address, the first access service nodedistributing a second connection identifier to an correspondent node ofthe second terminal according to the access identifier of thecorrespondent node in a source address in the data message, and storinga corresponding relationship between the second connection identifierand the access identifier of the correspondent node;

wherein, the second connection identifier is the same as or differentfrom the first connection identifier.

The present invention further provides a communication node applied toan access identifier and location separation network, comprising anaccess unit and a message forwarding unit, wherein:

the access unit is configured to establish, for each accessed terminal,a binding relationship between a first identifier of the terminal and atransmitting-receiving link;

the message forwarding unit is configured to, when receiving a datamessage sent from the terminal on the transmitting-receiving link, if asource address of the data message is a second identifier of theterminal, convert the source address to the first identifier of theterminal according to the binding relationship and then send the datamessage to a backbone network for forwarding; and, when receiving a datamessage whose destination address is the first identifier of theterminal, convert the first identifier to the second identifier, andforward the converted data message to the terminal through thetransmitting-receiving link corresponding to the first identifieraccording to the binding relationship.

Preferably, the first identifier is an access identifier of theterminal, and the second identifier is a private network IP address ofthe terminal, and the access identifier of the terminal is composed ofthe private network IP address of the terminal, and prefix/suffixinformation;

the message forwarding unit is configured to implement conversionbetween the first identifier and the second identifier by removing oradding the prefix/suffix information.

The present invention further provides a communication node applied toan access identifier and location separation network, comprising aconnection identifier distributing unit and an address converting unit,wherein:

the connection identifier distributing unit is configured to, whenreceiving a data message sent from an correspondent node to a terminal,distribute a connection identifier to the correspondent node of theterminal according to an access identifier of the correspondent node ina source address of the data message, and store a correspondingrelationship between the connection identifier and the access identifierof the correspondent node;

the address converting unit is configured to replace the source addressin the data message sent to the terminal with the connection identifieraccording to the corresponding relationship and then send the datamessage to the terminal; and, after receiving the data message using theconnection identifier as a destination address from the terminal,replace the destination address in the data message with the accessidentifier of the correspondent node according to the correspondingrelationship and then forward the data message to the correspondentnode.

Preferably, the communication node is an access service node in theaccess identifier and location separation network, or anintercommunication node for achieving intercommunication between theaccess identifier and location separation network and a legacy IPnetwork.

Preferably, the connection identifier distributing unit is configured todistribute the same or different connection identifiers to thecorrespondent nodes of different terminals.

The present invention has at least the following beneficial effects overthe existing solutions:

the configuration mode for identity recognition is clarified, and underthe architecture based on access identifier and location separation inthe network, a specific method for implementing identity recognition isprovided, and the processing performed by each network element isregulated;

the requirement for the number of the coding spaces is met, meanwhilethe present invention realizes the intercommunication andinterconnection with the legacy IP network, realizes the compatibilitywith the upper application programs of IPv4/IPv6, and supports thevarious application programs of the IPv4/IPv6 network to transplantsmoothly to the architecture based on access identifier and locationseparation in the network.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 illustrates the network topology of the architecture based onaccess identifier and location separation in the network according to anexample of the present invention.

FIG. 2( a) and FIG. 2( b) illustrate the network topologies of thearchitecture based on access identifier and location separation in thenetwork according to preferred examples of the present invention.

FIG. 3 illustrates the functional modules of the access service nodeaccording to an example of the present invention.

FIG. 4 illustrates the functional modules of the interconnection servicenode according to an example of the present invention.

FIG. 5 illustrates the connection relationship between nodes in anetwork based on identity and location separation architecture accordingto an example of the present invention.

FIG. 6 illustrates the process of addressing and forwarding when an AIDterminal receives and transmits a data message according to an exampleof the present invention.

FIG. 7 illustrates an intercommunication proxy server implementing thefunction of address conversion according to an example of the presentinvention.

PREFERRED EMBODIMENTS OF THE INVENTION

The technical scheme of the present invention will be further describedin detail below with reference to the drawings and examples.

Based on the proposal of the architecture based on access identifier andlocation separation in the network, the dual functions of identifieridentity and location of an IP address are separated to realize supportfor problems including mobility, multi-homeness, dynamic redistributionof IP addresses, reduction of route load, and inter-visit betweendifferent network areas in the next generation of internet.

The core concept of the architecture based on access identifier andlocation separation in the network is: there are two types ofidentifiers in the network, namely, access identifier (AID), andRouting-Location Identifier (RID). An AID is uniquely distributed toeach user in the network, and this AID keeps unchanged during theprocess of movement.

In a preferred example of the present invention, the schematic topologyof the architecture based on access identifier and location separationin the network is illustrated in FIG. 1. In this architecture, thenetwork is divided into access networks and a backbone network. Theaccess network is located on the edge of the backbone network and isresponsible for access of the terminals in the local network. Thebackbone network is responsible for routing and forwarding data messagesof the terminals accessing through the access networks. The AccessService Node (ASN) is located on the boundary point of the backbonenetwork and the access network, and connected with the access networkand the backbone network. The access network and the backbone network donot overlap in terms of topology relationship.

Wherein, in a network of the architecture based on access identifier andlocation separation (also referred to as the present architecturehereinafter), an AID is uniquely distributed to each user terminal, andthe AID is used in the access network and keeps unchanged during themovement process of the terminal; RID is a location identifierdistributed to the terminal and is used in the backbone network.

As shown in FIGS. 2( a) and 2(b), in a preferred example, the backbonenetwork in the present architecture is divided into a mapping forwardingplane and a general forwarding plane.

The general forwarding plane is mainly used to perform routing accordingto the RID in the data message and forward the data message using theRID as the destination address, and the data routing forwarding actionin the general forwarding plane is consistent with that in Legacy IPnetwork. The main network elements in the general forwarding planeinclude a CR (Common Router) and an ISN (Interconnect Service Node).

The mapping forwarding plane is mainly used to store theidentify-location mapping information (i.e., the AID-RID mappinginformation) of the terminal, process registration and inquiry of thelocation of the terminal, route and forward the data message taking theAID as the destination address. The main network elements of the mappingforwarding plane include an ILR/PTF (Identity Location Register/PacketTransfer Function).

In FIG. 2( a), the ASN is independent from the backbone network in thedivision of the architecture. In FIG. 2( b), the backbone networkincludes the ASN. FIG. 2( a) and FIG. 2( b) are only different indivision of architecture, and the function implemented by the ASN is thesame.

Referring to FIGS. 1, 2(a) and 2(b), the main network elements andfunctional entities involved in the architecture based on accessidentifier and location separation in the network are as follows:

user terminal: in the present architecture, the accessed user terminalmay be one or more of a mobile node, a fixed node and a nomadic node.

Access network: it provides a two-layer (physical layer and link layer)access service for the user terminal The Access network may be a basestation system, for example, a BSS (Base Station Subsystem), a RAN(Radio Access Network), an eNodeB (evolved Node B) and so on, or may bean xDSL (Digital Subscriber Line), an AP (Access Point) and so on.

ASN: it maintains the connection relationship between the user terminaland the backbone network, distributes RID to the user terminal,processes switch flow, processes registration flow, implementscharging/authentication, maintains/inquires the AID-RID mappingrelationship of the correspondent node, encapsulates, routes andforwards the data message sent to or from the terminal.

When the ASN receives a data message sent from the terminal, the ASNinquires a corresponding RID locally according to the AID of theCorrespondent Node (CN) in the data message: if a corresponding AID-RIDmapping item is found, the data message is forwarded to the backbonenetwork by way of replacing the AID with the RID in the data message, orby encapsulating the RID; if no corresponding AID-RID mapping item isfound, an inquiry flow is initiated to the ILR (Identity LocationRegister) to acquire the AID-RID mapping item, and then the data messageis forwarded by way of replacing the AID with the RID in the relateddata message, or by way of encapsulating the RID; or, the data messageis forwarded to the backbone network for route forwarding at themeantime of initiating an inquiry to the ILR, and after the AID-RIDmapping relationship returned by the ILR is received, the AID-RIDmapping is cached locally;

when receiving a data message sent from the network to the terminal, theASN sends the data message to the terminal after stripping out theexternal RID encapsulation.

The ASN is also responsible for acting for an IPV4/IPV6 terminal toachieve compatibility processing between an AID data message of thearchitecture based on access identifier and location separation in thenetwork and an IPV4/IPV6 data message.

CR (Common Router): it routes and forwards a data message using a RIDformat as a source address/destination address. The function of thiscommon router is the same as that of the router in the related art.

Authentication center: it is responsible for recording the userattributes including the user type, authentication information, the userservice level and so on in the network of the present architecture,generating user security information for authentication, integrityprotection and encryption, and implementing validity authentication andauthorization for a user after the user accesses. The authenticationcenter supports bi-directional authentication between the network of thepresent architecture and the user.

ILR/PTF (Identity Location Register/Packet Transfer Function): ILR andPTF may be two functional modules on the same entity and are located inthe mapping forwarding plane of the backbone network. ILRmaintains/stores the AID-RID mapping relationship of a user in thearchitecture based on access identifier and location separation in thenetwork, implements registration function, and processes the locationinquiry flow of the correspondent node; PTF, after receiving a datamessage sent by the ASN, routes according to the destination AID andforwards the data message. After the PTF node in the mapping forwardingplane finds the destination AID-RID mapping relationship, the RIDinformation is encapsulated in the header of the data message and thedata message is forwarded to the general forwarding plane and then isrouted to the correspondent node.

ISN (Interconnect Service Node): it is used to inquire, maintain theAID-RID mapping information of the terminal in the network of thepresent architecture, encapsulate, route and forward the data messagetransmitted between the network of the present architecture and theLegacy IP network, and implement the interconnecting andintercommunicating function between the network of the presentarchitecture and the Legacy IP network. When a mobile terminal switchesin the present architecture, the ISN serves as an agent anchor point ofthe mobile terminal between the network of the present architecture andthe Legacy IP.

As shown in FIG. 3, an ASN comprises the following functional modules:an access processing module 31, which is configured to cooperate withthe terminal and the authentication center to accomplish authenticationfor the terminal when the terminal requests to access, establish aconnection with the terminal through the access network, distribute aRID to the terminal, and inform a registration module to initiateregistration for the terminal;

a registration module 32, which is configured to, after receiving anotification of registration for the terminal, initiate a registration,which carries the current AID-RID mapping information of the terminal,to the home domain ILR of the terminal; and after receiving anotification of canceling registration for the terminal, notify theterminal home domain ILR to delete the registration information of theterminal, including the AID-RID mapping information of the terminal;

a connection maintaining module 33, which is configured to, during theon-line period after the terminal accesses, maintain the connectionbetween the local ASN and the terminal; and maintain the connectionbetween the local ASN and the ASN to which the correspondent nodeaccesses when the terminal communicates;

a mapping managing module 34, which is configured to cache and maintainthe AID-RID mapping information of the terminal after the terminalaccesses, and inquire the corresponding RID to the ILR of the mappingforwarding plane according to the AID of the correspondent node afterreceiving an inquiry notification and locally maintain the inquiredAID-RID mapping information;

an off-line processing module 35, which is configured to, after theterminal accessing to the local ASN is off line, notify the connectionmaintaining module to release the related connection between theterminal and the network, notify the mapping managing module to deletethe AID-RID mapping information of the terminal, and notify theregistration module to cancel registration for the terminal;

a message forwarding module 36, which is configured to encapsulate thedata message sent by the terminal accessing to the local ASN with theRIDs of the terminal and the correspondent node, route and forward tothe ASN to which the correspondent node accesses, and decapsulate thedata message to be sent to the terminal accessing to the local ASN andthen send to the terminal;

wherein, the message forwarding module 36 is further divided into afirst forwarding unit and a second forwarding unit, wherein:

the first forwarding unit is configured to, after receiving a datamessage sent by the terminal accessing to the local ASN, inquire thelocally cached AID-RID mapping information according to the AID of thecorrespondent node as the destination address in the data message, andif the RID of the correspondent node is inquired, encapsulate the RID ofthe correspondent node, as a destination address, and the RID of theterminal, as a source address, into the data message (for example, theycan be encapsulated in the three-layer message header newly added to thedata message), and then forward the encapsulated data message to thegeneral forwarding plane; if the RID of the correspondent node is notinquired, perform tunnel encapsulation for the data message and thenforward to the mapping forwarding plane, and notify the mapping managingmodule to inquire the RID of the correspondent node;

the second forwarding unit is configured to, after receiving a datamessage to be sent to the terminal accessing to the local ASN, strip outthe RID encapsulated in the data message, restore to the format of thedata message sent from the correspondent node to the ASN and then sendto the terminal through the connection between the local ASN and theterminal;

a switch controlling module 37, which is divided into a switch-outcontrolling unit and a switch-in controlling unit, wherein:

the switch-out controlling unit is configured to, after receiving aswitch request, when determining that the terminal is to switch toanother ASN (called as switch-in ASN) according to the destinationaddress of the switch, request the switch-in ASN for a switch, andnotify the terminal to access to the switch-in ASN after receiving aresponse, forward the data message sent to the terminal received duringthe switch to the switch-in ASN, and notify the mapping managing moduleto delete the AID-RID mapping information of the terminal aftercompletion of the switch; or, send the information of the correspondentnode of the terminal to the switch-in ASN or the mapping forwardingplane during the switch;

the switch-in controlling unit is configured to, after receiving aswitch request, distribute a RID to the terminal and store the AID-RIDmapping information of the terminal, obtain the information of thecorrespondent node of the terminal from the switch-out ASN and return aswitch response, and notify the registration module to initiate aregistration flow for the location update of the terminal; the switch-incontrolling unit may be further configured to notify the ASNs to whichall the correspondent nodes of the terminal access or the ISN anchoredwhen the terminal communicates with the terminal of the Legacy IPnetwork to update the AID-RID mapping information of the terminal

The network of the present architecture is compatible with the IPV4/IPV6terminal (refer to the terminal in the existing Legacy IP network thatsupports IPV4/IPV6 protocol stack), and when the format of the AID isdifferent from that of IPV4/IPV6 address, the ASN needs to act for theIPV4/IPV6 terminal to realize the compatibility processing between thenetwork AID data message and the IPV4/IPV6 data message. Thus, a formatconverting module 38 needs to be added to the ASN, and the formatconverting module 38 is configured to covert the IPV4/IPV6 address (maybe the source address, or the source address and the destinationaddress) of the terminal in the network of the present architecture inthe data message sent by the IPV4/IPV6 terminal accessing to the localASN to the corresponding AID, and convert all AIDs in the data messageto be sent to the IPV4/IPV6 terminal to the IPV4/IPV6 address.

As shown in FIG. 4, an ISN comprises the following functional modules:

a connection maintaining module 41, which is configured to establish andmaintain a connection between a terminal in the network of the presentarchitecture and a terminal of the Legacy IP network, and when theterminal of the network of the present architecture switches, act as anagent anchor point of the terminal between the network of the presentarchitecture and the Legacy IP to keep the connection with the terminalin the Legacy IP network;

a mapping managing module 42, which is configured to extract andmaintain the AID-RID mapping information of the terminal in the networkof the present architecture in the data message, and inquire thecorresponding RID to the ILR of the mapping forwarding plane accordingto the AID of the terminal to be inquired after receiving an inquirynotification and locally maintain the inquired AID-RID mappinginformation;

a message forwarding module 43, which is further divided into a firstforwarding unit and a second forwarding unit, wherein,

the first forwarding unit is configured to inquire the locally cachedAID-RID mapping information according to the AID (as the destinationaddress or obtained through conversion according to the destinationaddress) of the terminal in the network of the present architecture inthe data message sent from the Legacy IP network: if the RIDcorresponding to the AID of the terminal in the network of the presentarchitecture is found, the RID of the terminal in the network of thepresent architecture is encapsulated, as a destination address, into thedata message (for example, it is encapsulated in the newly addedthree-layer message header), and then the encapsulated data message isforwarded to the general forwarding plane; if the RID corresponding tothe AID of the terminal in the network of the present architecture isnot found (for example, the data message is the first packet or is adata message of a defaulted route), tunnel encapsulation is performed onthe data message and then the data message is forwarded to the mappingforwarding plane, and the mapping managing module is notified to inquirethe RID of the terminal in the network of the present architecture;

the second forwarding unit is configured to, after receiving a datamessage sent from the network of the present architecture, strip out theRID encapsulated in the data message, and send the data message to theterminal in the Legacy IP network or the format converting module.

If the format of the AID adopted in the network of the presentarchitecture is different from that of the IPV4/IPV6 address, the ISLfurther comprises a format converting module 44, which is configured toconvert the IPV4/IPV6 address of the terminal in the network of thepresent architecture included in the data message sent from the LegacyIP network into the corresponding AID, and then send to the firstforwarding unit to forward; and convert the AID of the terminal of thenetwork of the present architecture in the data message decapsulated bythe second forwarding unit into an IPV4/IPV6 address format and thensend to the terminal in the Legacy IP network.

As shown in FIG. 5, the main interfaces of the present architecturecomprise:

S1/D1 interface, which is an interface (or called as a reference point)between a terminal and an ASN. Wherein:

S1 is a signaling interface between the terminal and the ASN, and ismainly used for message flow processing including access management,switch, authentication, charging and registration.

D1 is a data transmitting-receiving interface between the terminal andthe ASN. For a terminal compatible with the network of the presentarchitecture, the format of the data message of the D1 interface is:

Two-layer Source Destination Payload of the data message . . . messageheader AID AID

wherein, the source AID is the AID of the terminal sending a datamessage, and is used as the source address of the data message; thedestination AID is the AID of the correspondent node to which the datamessage is sent, and is used as the destination address of the datamessage; the source address and the destination address are encapsulatedin the three-layer message header.

S2/D2 interface, which is an interface between ASNs. Wherein:

S2 is mainly used for transmission of switch managing signaling duringswitch, and transmitting a RID update message when the location of thecorrespondent node changes.

D2 is mainly used to forward data between ASNs during switch. The formatof the data message of the D2 interface is:

Two-layer Tunnel Source Destination Payload of the data messageEncapsulation AID AID message . . . header

Before forwarding the data message, the ASN adds tunnel encapsulation tothe data message. There are various ways for tunnel encapsulation, forexample, L2TPv3, IP-in-IP, MPLS (LDP-based and RSVP-TE based), GRE andIPsec, and the present invention is not limited to any particular way oftunnel encapsulation.

S3 is a signaling interface between an ASN and an ISN. During thecommunication between the terminal of the network of the presentarchitecture and the terminal of the Legacy IP network, if the terminalof the network of the present architecture switches, the ASN will informthe ISN of the new AID-RID mapping information of the terminal of thenetwork of the present architecture through the S3 interface.

D3 is an external interface with the general forwarding plane, and theformat of the data message of the D3 interface is:

Two-layer Source Destination Source Destination Payload message RID RIDAID AID of the data header message . . .

The data message of the D3 interface is encapsulated with a newthree-layer message header based on the data message of the D1interface, and the new three-layer message header comprises a source RIDand a destination RID, wherein, the source RID is the RID distributed tothe terminal sending a data packet, while the destination RID is the RIDdistributed to the correspondent node to which the data packet is sent.However, this encapsulation mode is not unique.

S4 is a signaling interface between the ASN and the mapping forwardingplane, and is mainly used to inquire and maintain AID-RID mappinginformation.

D4 m is a data forwarding interface between the ASN and the mappingforwarding plane, and the format of the data message of the D4 minterface is:

Two-layer Source RIDi Source Destination Payload of the data message RIDAID AID message . . . header

The data message of the D4 m interface is also encapsulated with a newthree-layer message header based on the data message of the D1interface, and the source address of the new three-layer message headeris the source RID, and its destination address is RIDi, wherein, thesource RID is the RID distributed to the terminal sending a data packet,while the RIDi is the routing address of ILR/PTF in the mappingforwarding plane connected with the ASN, and is obtained from theconfiguration data on the ASN.

S5 is a signaling interface between ILRs in the mapping forwardingplane, and is mainly used for inquiring and maintaining the AID-RIDmapping information, and the routing information interaction within themapping forwarding plane.

Di interface is a data forwarding interface between the network of thepresent architecture and the Legacy IP network, and the format of thedata message of the Di interface is the same as that of the data messageof the Legacy IP network, which is as follows:

Two-layer Source Destination Payload of the data message . . . messageIPV4/IPV6 IPV4/IPV6 header

In view of the progressive characteristic of network evolution, theterminal in the present architecture mainly has two types:

IPV4/IPV6 terminal, which refers to a terminal supporting the existingIPV4/IPV6 protocol stack in the Legacy IP network;

AID terminal, which refers to a terminal whose protocol stack has beenupgraded to be able to support the AID coding requirement, wherein, theIPV4/IPV6 address layer in the previous IPV4/IPV6 protocol stack isexpanded to be able to support an AID coding address with expandedIPV4/IPV6 address bit length; meanwhile, compatibility processing isalso performed at the terminal for the upper-layer service application.The ASN further needs to support the access managing function of the AIDterminal and the IPV4/IPV6 terminal, and achieves AID agency functionfor the IPV4/IPV6 terminal, and is responsible for acting for theIPV4/IPV6 terminal to realize the compatibility processing between theAID data message of the architecture based on access identifier andlocation separation in the network and the IPV4/IPV6 data message.

The method for implementing access identification of a user terminalwithin the network of the present architecture, i.e., the AID codingmechanism, will be described below by taking an IPV4 terminal as anexample. The embodiments involved in this text are also applicable to anIPV6 terminal.

In view of the architecture based on access identifier and locationseparation in the network per se, the requirement for AID coding is justmeeting the requirement for the number of coding spaces, i.e., themaximum coding length of AID should meet the requirement on the maximumnumber of nodes.

However, at the meantime of the AID meeting the requirement for thenumber of coding spaces, the interconnection and intercommunication withthe traditional IP network and the compatibility with the upper-layerapplication should also be taken into consideration such that thevarious application programs of the IPV4 network can transplant smoothlyto the architecture based on access identifier and location separationin the network. Therefore, the emphases needing to be considered for theAID coding mechanism comprise the followings.

1) Most of the application programs in the existing network areapplication based on IPV4, so the AID coding mechanism should becompatible with the format of the IPV4 address in order to be compatiblewith the upper-layer application program;

2) the terminal in the present architecture needs to visit theapplication in the Legacy IPV4 network, and has a demand forintercommunicating with the Legacy IPV4 network, so the coding space ofAID and the IPV4 address space of the Legacy IPV4 network should nothave ambiguity so that the visited correspondent node can be uniquelydistinguished;

3) the network architecture based on an identity location separationarchitecture serves as an expansion component of a traditional LegacyIPV4 network, and the coding space of AID should conform to the IPaddress layer coding regulations in the traditional Legacy IPV4 network.On the interface for interconnection and intercommunication with thetraditional Legacy IPV4 network, AID adopts a private network address ofIPV4, or a public IPV4 address that is specially distributed to thenetwork of the network architecture based on the identity locationseparation architecture.

Based on the consideration for the above factors, this example providesa specific method for implementing access identification based on thepresent architecture, wherein the AID format is defined as: ExpandHeader (EH)+suffix(suffix32). The AID is used to identify thecorrespondent node within the network architecture based on identitylocation separation architecture, and an AID uniquely identifies a useridentity. An IPV4 address is adopted to uniquely identify thecorrespondent node for intercommunication with the Legacy IPV4.

Wherein, the value of 32 bit of suffix, suffix32, is the private networkaddress in IPV4 format, and the bit length of the EH and its value aresingularly defined as needed within the architecture based on identitylocation separation. In this way, the expand header of the AID isremoved to covert to the corresponding IP address, and the IP address isconverted to the corresponding AID by adding a constant as the expandheader. As a variation of this example, the coding format of AID mayalso adopt the format of an IPV4 public network address plus a constantas a suffix, and the coding format of AID may further adopt the formatof an IPV4 private network address plus a constant as a suffix.

Description will be made in this example for the case where an IPV4private network address is used for the suffix part of the AID. When thesuffix suffix32 is an IPV4 private network address, in view of a LegacyIPV4 network, the architecture based on access identifier and locationseparation communicates, as a private network of the Legacy IPV4network, with the Legacy IP network; and the IPV4 terminal in thearchitecture based on access identifier and location separation accessesto the network as a private network node in the Legacy IPV4 network andcommunicates with other nodes.

When a user uses a terminal to communicate in the network of the presentarchitecture, the mode for configuring an AID for the terminal may beone of the following modes, and different modes may be adopted fordifferent terminals.

The first is a mode of configuring by the network, i.e., the AID of theuser is stored in the authentication center, the user identifier is sentto the authentication center when the terminal is authenticated, theauthentication center sends the AID together with the user identifier tothe ASN, the ASN stores the AID and sends it to the terminal. When theterminal is an IPV4/IPV6 terminal, the ASN needs to convert the AID tothe corresponding IPV4/IPV6 address before sending it to the terminal.

Network users of different standards have different user identifiers,for example, the user identifier is international Mobile SubscriberIdentification (IMSI) in the cellular mobile communications network,while in fixed networks like ADSL, the user identifier is network accessidentification (NAI) or user name (Username).

The second is the mode of configuring by the terminal, i.e., the AID isstored in a user identification module (such as a SIM card, a UIM cardand so on) of the terminal, and the terminal configures thecorresponding IPV4 address in the protocol stack. When the terminalaccesses to the network, the terminal reads AID information from theSIM/UIM card, the AID is sent to the ASN in an access signaling, and theASN stores the AID of the terminal. The AID terminal (referring to theterminal where the protocol stack supports AID coding requirement)directly uses the AID for the source address in the transmitted datamessage, the source address in the data message sent by the IPV4/IPV6terminal adopts an IPV4/IPV6 address corresponding to the AID of theterminal, and the ASN converts it to the corresponding AID.

In the network of the present architecture, the RID number may adopt theformat of IPV4/IPv6 address universally supported by the routers in theexisting Legacy IP network to indicate the current ASN location of theterminal The action scope of the RID is in the general forwarding planeof the backbone network of the network of the present architecture.

The backbone network of the network of the present architecture performsrouting forwarding using the format of data message. When the terminalregisters or switches to the network, the ASN distributes a RID to theterminal according to a predetermined policy, and the RID distributed bythe ASN should point to the ASN. According to service requirements, theASN may distribute one or more specialized RIDs to the terminal, ordistribute the same RID to a plurality of terminals.

The present architecture is based on the technology principle oflocation and identity separation, the main affecting factors for thenetwork topology in the general forwarding plane are the number anddeploying mode of the functional entities such as ASN and ISN, and thelocation change of the accessed terminal has no direct relation with thenetwork topology, thereby eliminating the influence of the mobility ofthe terminal host on the measurability of the routing system. In theLegacy IP network, the basis of routing is the IP address, this IPaddress is basically one-to-one corresponding to the number ofcommunication hosts, and the scale of the routing table is positivelycorrelated with the number of the communication hosts. Especially in ascene of IPV4/IPV6 dual-stack, the scale of the routing table willincrease exponentially. Large scale of the routing table and itsfrequent change will cause increase of the time for routing convergence.RID is used as the routing basis in the general forwarding plane in thepresent architecture, ASN and ISN can distribute to a plurality ofaccessed users the same RID, which indicates the locations of the ASNand ISN. From this viewpoint, the number of routing items in the generalforwarding plane is mainly positively correlated with the numbers of ASNand ISN, thereby reducing the relevance with the number of accessedusers. The complexity of network topology is reduced by solving themobility problem, and the relevance between the scale of the routingtable and the number of accessed users is reduced by way of a pluralityof accessed terminals sharing a RID, thus increasing the measurabilityof the routing system.

The operation process of how to use the above AID coding to implementaddressing and forwarding of a data message when terminals in thepresent architecture communicate with each other, or the terminal in thepresent architecture communicates with a terminal in the traditional IPnetwork will be described below in further detail with reference to thedrawings and the specific examples.

EXAMPLE ONE

Description will be made in this example in terms of the interactionprocess between an IPV4 terminal in the network of the presentarchitecture and an AID terminal.

The flow of interaction between terminals within the presentarchitecture will be described in this example by using, for example, anIPV4 terminal as a source terminal and an AID terminal as a destinationterminal. The source address and destination address of the data messagetransmitted and received by the IPV4 terminal is of the IPV4 format.When a data message sent to the IPV4 terminal is received, the sourceAID and destination AID carried in the data message are of the format ofexpand header+IPV4 address, the ASN strips out the expand header portionof the source AID and the destination AID to convent to an IPV4 addressformat identifiable to the IPV4 terminal, and then forwards it to theIPV4 terminal; when a data message sent from the IPV4 terminal isreceived, the ASN needs to convert the source address and thedestination address of the IPV4 format to the corresponding AIDs. Thespecific flow is as follows.

Step 1, when an IPV4 terminal MN accesses to the network of the presentarchitecture, a unique point-to-point connection relationship with theASN is established, and through this point-to-point connectionrelationship, the ASN can uniquely find the corresponding IPV4 terminal.

Specifically, this point-to-point connection relationship is a GTP (GPRSTunneling protocol) connection in mobile standard of GSM (Global Systemfor Mobile Communications)/WCDMA (Wideband Code Division MultipleAccess)/TD-SCDMA (Time Division-Synchronous CDMA); this point-to-pointconnection relationship is a PPP (Point to Point Protocol) connection ina CDMA mobile standard; and in a fixed broadband access network, thispoint-to-point connection relationship is a PPP connection.

The ASN will store the binding relationship between the AID identifierof the MN and the point-to-point connection relationship, which is asshown in the following FIG. 1:

point-to-point connection relationship AID1 Connect1 point-to-pointconnection relationship AID2 Connect2 point-to-point connectionrelationship AID3 Connect3 . . . . . . point-to-point connectionrelationship AIDn Connectn

Step 2, the AID terminal in the network of the present architecture, CN,sends a data message to MN, the source address of the data message sentby CN is the AID of CN, and the destination address is the AID of MN,and the formats of the source address and the destination address areboth expand header+IPV4 address, as shown in the following FIG. 2:

Source AID Destination Payload of the data message . . . AID

Step 3, when the ASN where the CN is located receives a data messagesent by the CN, the ASN searches for and encapsulates the RID of CN andthe RID of MN and then sends the data message to the ASN where the MN islocated through the backbone network.

Step 4, since the terminal MN may communicate with a plurality of CNssimultaneously, when the MN responds with a data message subsequently,the MN cannot uniquely correspond to the CN only according to the IPV4private network address of the CN, so when the ASN where the MN islocated receives a data message sent to the MN, the ASN will distributesa connection identifier SN to the source AID in the data message so asto uniquely determine the correspondent node, wherein the SN is of theformat of IPV4 address and uniquely identifies a connection identifierin the communication connection corresponding to the MN.

A correspondent node table will be stored in the ASN, wherein, thecorresponding relationship between the AID of the correspondent node ofeach terminal and the SN is stored, for example, as shown in thefollowing table 3:

AID1 Correspondent Correspondent . . . Correspondent AID11/SN1 AID12/SN2AID1n/SNn AID2 Correspondent Correspondent . . . Correspondent AID21/SN1AID22/SN2 AID2m/SNm . . . AIDn Correspondent Correspondent . . .Correspondent AIDn1/SN1 AIDn2/SN2 AIDns/SNs

wherein, AID11, AID12, . . . AID1 n refer to the AIDs of the 1^(st) tothe n^(th) correspondent node of the terminal AID1 respectively; SN1,SN2, . . . SNn refer to the SNs distributed to the 1^(st) to the n^(th)correspondent node of the terminal AID1 respectively.

Step 4, the ASN where the MN is located replaces the destination AIDwith the IPV4 address portion of the destination AID and writes the IPV4address portion of the destination AID in the destination address unititem in the data message, replaces the source AID with the SN (in theIPV4 address format) as the source address unit item, and then inquiresthe binding relationship in Table 1 through the AID of the MN to obtainthe corresponding point-to-point connection relationship, and send theconverted data message to the MN through the point-to-point connectionrelationship.

The format of the converted data message is as follows.

Source SN Destination Payload of the data message . . . IPV4 address

Step 5, the ASN where the MN is located receives the data messageresponded by the MN, wherein the source address in the data message isthe IPV4 address portion of MN, and the destination address is SN, andthe format of the data message is as follows.

Source IPV4 Destination SN Payload of the data message . . . address

Step 6, since the source IPV4 address may be a private network address,and other accessed terminals may also use the same address, the datamessage transmitted and received by the MN cannot be identified throughthe source IPV4 address. Therefore, the ASN always keeps apoint-to-point connection relationship with each accessed terminal, andthe forwarding path of the data message sent to or sent from theterminal always passes by this point-to-point connection. Thus, the datamessage stream transmitted and received by the terminal can be uniquelydetermined through the point-to-point connection. After the ASN wherethe MN is located receives the data message sent by the MN, the bindingrelationship in Table 1 is inquired according to the point-to-pointconnection relationship of MN to obtain the corresponding AID, and thesource IPV4 address in the data message is replaced with thecorresponding AID.

Step 7, the ASN where the MN is located inquires Table 3 according tothe destination address SN (in the IPV4 address format) filled by MN,and replaces SN with the AID of CN according to the correspondingrelationship between the SN and the AID of CN. At the moment, the formatof the data message is:

Source AID Destination Payload of the data message . . . AID

Step 8, after the ASN where the MN is located finishes processingincluding RID encapsulation of the data message, the ASN sends the datamessage to the backbone network for forwarding processing, and thebackbone network routes and forwards the data message to the ASN wherethe CN is located according to the RID encapsulated in the data message.

By now, a complete addressing and transmitting-receiving process of adata message is completed.

Wherein, the distribution scheme for the SN occupying the IPV4 addressfield may adopt the following mode:

when the IPV4 address is planned, the IPV4 address field occupied by theSN is of a monopolization mode so as to avoid ambiguity. The number ofthe IPV4 address fields monopolized by the SN should be no less than thenumber of possible end-to-end connections of each terminal node. Thefield of IPV4 address may be a public network IP address, or a privatenetwork IP address. When a private network address space is used, withinthe range of the architecture based on access identifier and locationseparation in the network, the private network address occupied by theSN cannot be used for other applications so as to avoid overlappingdistribution with the IPV4 address portion constituting the AID (whoseformat is Expand Header+IPV4 address) access identifier.

In the point-to-point connection between a terminal A and an ASN, the SNis used to identity the end-to-end data stream between the terminal Aand different correspondent nodes. When the ASN distributes the SN, itshould be ensured that the SNs distributed to the same terminal accessedunder the ASN are not repeated, and the SNs distributed to differentterminals may be repeated. For example:

two terminals accessed under the ASN are terminal A1 and terminal A2respectively, the correspondent nodes keeping a communicationrelationship with the terminal Al include correspondent nodes B1, B2 andB3, and the correspondent nodes keeping a communication relationshipwith the terminal A2 include correspondent nodes C1, B2 and C3.

The ASN will distribute different SN1, SN2 and SN3 to the end-to-endconnections A1-B1, A1-B2 and A1-B3. Wherein, SN1, SN2 and SN3 aredifferent IPV4 addresses respectively.

Meanwhile, the ASN will distribute different SN1, SN2 and SN3 to theend-to-end connections A2-C1, A2-B2 and A2-C3, wherein, SN1, SN2 and SN3are different IPV4 addresses respectively, but their values may the sameas that of the SN occupied by A1.

Example Two

Description will be made in this example on the addressing andforwarding process of a data message when the terminals within thenetwork of the present architecture interact with each other by takingan AID terminal as an example.

FIG. 6 illustrates the whole sending flow of uplink and downlink datamessages of an AID terminal. As shown in FIG. 6, the process mainlycomprises the following steps:

step 301, ASN1 where terminal UE1 is located receiving a data messagesent from UE1, wherein the source address and the destination addresscarried in the data message are both in the AID coding format;

step 302, ASN1 searching for the corresponding destination RID locallyaccording to the destination AID; if the corresponding destination RIDis found, executing step 305; otherwise, executing step 303;

step 303, sending a mapping inquiry request to the mapping forwardingplane, and meanwhile forwarding the data message to the mappingforwarding plane to process;

wherein, when the ASN cannot find mapping information locally, the ASNmay determine whether first-packet forwarding is needed according to theconfiguration policy, and if yes, the ASN forwards the data message tothe mapping forwarding plane to forward at the same time; iffirst-packet forwarding is not needed and the first-packet policy isdiscarding, then the data message is discarded; if first-packetforwarding is not needed and the first-packet policy is storing, thenthe data message is stored.

Step 304, the mapping forwarding plane inquiring the correspondingdestination RID according to the mapping inquiry request sent by ASN1and the data message, and inquiring the RID corresponding to the sourceAID;

step 304 a, encapsulating the inquired RID in the header of the datamessage (for example, adding the destination RID routing information tothe data message), and forwarding to the general forwarding plane;

step 304 b, the mapping forwarding plane returning the inquired AID-RIDmapping to ASN1 through a mapping inquiry response message;

after the ASN receives the response, the ASN stores the AID-RID mappinginformation thereof in the local buffer; in addition, the ASN stores thedata message before the response is received.

The order of step 304 a and step 304 b is not defined in the presentinvention.

Step 305, ASN1 performing data message encapsulation according to theinquired destination RID and source RID and then forwarding the datamessage to the general forwarding plane after encapsulation;

step 306, the general forwarding plane routing and forwarding to ASN2according to the RID encapsulated in the external layer of the datamessage;

step 307, upon receiving the data message sent to UE2, ASN2 performingdecapsulating processing to the data message, stripping out the RID, andsending the data message to UE2;

meanwhile, ASN2 learns the source RID-AID mapping in the data message,i.e., if when ASN2 receives the data message, ASN2 inquires the mappinginformation in the local buffer, and if the local buffer does not storethe source RID-AID mapping information, i.e., the mapping information ofUE1, the mapping information of UE1 is stored locally according to thesource RID and AID in the data message.

Step 308, UE2 responding with a data message, wherein the source addressand destination address are in the AID coding format;

step 309, after receiving the responded data message, ASN2 inquiring thelocally cached mapping information according to the destination AID inthe data message;

since ASN2 has learned the mapping relationship of UE1 in the aboveflow, the mapping relationship can be found locally in ASN2;

step 310, ASN2 encapsulating the inquired RID and then sending to thegeneral forwarding plane;

step 311, the general forwarding plane sending the data message to ASN1according to the external layer RID;

step 312, ASN1 decapsulating the data message, stripping out the RIDencapsulation, and then sending the data message to UE1.

When ASN1 receives the responded data message, after decapsulation, ASN1can inquire whether the ASN2-UE2 mapping relationship has been learned(it should have been learned in normal cases, but the case where theresponded data message arrives first is not excluded), and if it has notbeen learned, then the mapping relationship is learned so that themapping relationship inquiry does not need to be performed in themapping forwarding plane for subsequent data messages.

By now, a complete process of data interaction is completed.

EXAMPLE THREE

As shown in FIG. 7, in a preferred example, the AID within thearchitecture based on identity location separation is translated to anIPV4 public network address by incorporating an intercommunication node(for example, an intercommunication proxy server) between an IPV4network and a network architecture based on identity and locationseparation architecture, thereby achieving interconnection andintercommunication between the present architecture and the IPV4network. This intercommunication proxy server may be disposed within anISN.

The terminal uses an AID to identify the correspondent node within thenetwork based on identity and location separation architecture, and anIPV4 public network address is used when the internal terminal intendsto communicate with an external Internet network (for example, an IPV4network). The intercommunication proxy server is responsible forconverting the internal AID address (expand header+IPV4 private networkaddress) to an IPV4 public network address so that it is used normallyin an external public network. Wherein, for the implementation of thespecific converting function of the intercommunication proxy server,reference may be made to the NAT (Network Address Translation) device inthe existing network, which converts a private network address to apublic network address by way of a private network address+a portnumber; the intercommunication proxy server only differs from the NATdevice in that a private network address with an expand header isconverted to a public network address.

On the contrary, when a first terminal in a traditional IPV4 networkcommunicates with a second terminal in the network of the presentarchitecture, the intercommunication proxy server distributes to thesecond terminal a connection identifier, which may adopt an IP publicnetwork or private network address, identifiable to the first terminal,and stores the corresponding relationship between the connectionidentifier and the AID of the second terminal. The first terminal usesthis connection identifier to communicate with the second terminal, andthe intercommunication proxy server obtains the AID of the secondterminal according to the corresponding relationship between theconnection identifier and the AID of the second terminal, and realizesthe conversion between the AID of the second terminal and thecorresponding connection identifier.

The above examples are all descriptions on an IPV4 terminal or an AIDterminal, and the implementing mechanism where the AID is in an IPV6format will be further described in detail below.

In the present architecture, an IPV6 address coding format may be usedas the coding of the AID, and the AID adopts 128 bit coding. The formatof the AID is: 96 bit Expand Header+32 bit suffix32 (IPV4 privatenetwork address).

There is enough address space when an IPV6 coding format is adopted, andthe requirement on a larger number of AID coding spaces can be met. Theexisting devices can support the IPV6 protocol stack very well, andindustrialization level of the adaptive modification of the upper-layerapplication for IPV6 is quite high. The terminal supporting IPV6protocol stack can be used as the accessed terminal in the architecturebased on identity and location separation without any change, AID may beentered at the terminal and the correspondent may be identified by theAID, and direct end-to-end intercommunication is supported.

The network based on identity and location separation architecture canbe used to rich and supplement the IPV6 protocol stack, and serves as acomponent of the IPV6 protocol stack.

The present invention further provides a communication node applied toan access identifier and location separation network, comprising anaccess unit and a message forwarding unit, wherein:

the access unit is configured to establish, for each accessed terminal,a binding relationship between a first identifier of the terminal and atransmitting-receiving link;

the message forwarding unit is configured to, when receiving a datamessage sent from the terminal on the transmitting-receiving link, if asource address of the data message is a second identifier of theterminal, convert the source address to the first identifier of theterminal according to the binding relationship and then send the datamessage to a backbone network for forwarding; and, when receiving a datamessage whose destination address is the first identifier of theterminal, convert the first identifier to the second identifier, andforward the converted data message to the terminal through thetransmitting-receiving link corresponding to the first identifieraccording to the binding relationship.

Wherein, the first identifier is an identity identifier of the terminal,and the second identifier is a private network IP address of theterminal, and the identity identifier of the terminal is composed of theprivate network IP address of the terminal, and prefix/suffixinformation;

the message forwarding unit is configured to implement conversionbetween the first identifier and the second identifier by removing oradding the prefix/suffix information.

The example of the present invention further provides anothercommunication node applied to an access identifier and locationseparation network, comprising a connection identifier distributing unitand an address converting unit, wherein:

the connection identifier distributing unit is configured to, whenreceiving a data message sent from an correspondent node to a terminal,distribute a connection identifier to the correspondent node of theterminal according to an identity identifier of the correspondent nodein a source address of the data message, and store a correspondingrelationship between the connection identifier and the identityidentifier of the correspondent node;

the address converting unit is configured to replace the source addressin the data message sent to the terminal with the connection identifieraccording to the corresponding relationship and then send the datamessage to the terminal; and, after receiving the data message using theconnection identifier as a destination address from the terminal,replace the destination address in the data message with the identityidentifier of the correspondent node according to the correspondingrelationship and then forward the data message to the correspondentnode.

Wherein, the communication node is an access service node in theidentity identifier and location separation network, or anintercommunication node for achieving intercommunication between theidentity identifier and location separation network and a legacy IPnetwork.

Wherein, the connection identifier distributing unit may distribute thesame or different connection identifiers to the correspondent nodes ofdifferent terminals.

In conclusion, when the present invention incorporates the architecturebased on access identifier and location separation in the network, sincethe architecture changes the logical meaning of the terminal IP addresslayer, the dual meaning of location identifier and access identifier ofthe original IP address layer is changed to only identifying the useridentifier without the logical meaning of location identifier. Whenmixed networking is implemented using the network of the presentarchitecture and the traditional IP (i.e., Legacy IP) network, theaccess identifier of the terminal in the network of the presentarchitecture adopts an IPV4/IPV6 address, corresponding processing isperformed through identifying two different meanings, the accessrecognition defined in the architecture based on access identifier andlocation separation in the network is distinguished from the IP addressof the Legacy IP network, thereby solving the problem of scarcity ofIPV4/IPV6 address space caused by that dynamic distribution cannot beimplemented for the access recognition is assigned to a certain userexclusively under the architecture based on access identifier andlocation separation in the network.

A person having ordinary skill in the art can appreciate that all orpart of the steps in the above step can be implemented by instructingrelated hardware through a grogram, which may be stored in a computerreadable storage medium, such as read-only memory, disk or an opticaldisk, and so on. Optionally, all or part of the steps in the aboveexamples can be also implemented using one or more integrated circuits.Correspondingly, each module/unit in the above examples can beimplemented in the form of hardware, or in the form of softwarefunctional module. The present invention is not limited to any specificform of combination of hardware and software.

Although the present invention is described with reference to particularexamples, a person having ordinary skill in the art can makemodifications and transformations without departing from the sprit orscope of the present invention. Such modifications and transformations,however, shall be regarded as within the scope of the description andthe scope of the attached claims.

INDUSTRIAL APPLICABILITY

The present invention provides a communication method, and a method forforwarding a data message during the communication process and acommunication node, wherein, the configuration mode for identityrecognition is clarified, and under the architecture based on accessidentifier and location separation in the network, a specific method forimplementing identity recognition is provided, and the processingperformed by each network element is regulated; the requirement for thenumber of the coding spaces is met, meanwhile the present inventionrealizes the intercommunication and interconnection with the legacy IPnetwork, realizes the compatibility with the upper application programsof IPv4/IPv6, and supports the various application programs of theIPv4/IPv6 network to transplant smoothly to the architecture based onaccess identifier and location separation in the network.

1. A communication method applied to an access identifier and locationseparation network, comprising: an access service node establishing, foreach accessed terminal, a binding relationship between a firstidentifier of the terminal and a transmitting-receiving link; and whenreceiving a data message sent from the terminal on thetransmitting-receiving link, if a source address of the data message isa second identifier of the terminal, the access service node convertingthe source address to the first identifier of the terminal according tothe binding relationship and then sending the data message to a backbonenetwork for forwarding.
 2. The method according to claim 1, wherein, thefirst identifier is an access identifier of the terminal, and the secondidentifier is a private network IP address of the terminal.
 3. Themethod according to claim 2, wherein, the access identifier of theterminal comprises the private network IP address of the terminal, andprefix/suffix information; and/or, the access identifier of the terminaladopts an address coding format of IPV6.
 4. The method according toclaim 3, wherein, the prefix/suffix information is a constant orvariable determined based on the access identifier and locationseparation network.
 5. The method according to claim 1, wherein, thetransmitting-receiving link is a point-to-point connection relationshipestablished by the access service node for the terminal.
 6. The methodaccording to claim 5, wherein, the point-to-point connectionrelationship is a General Packet Radio Service Tunneling Protocol (GTP)connection or a point-to-point protocol (PPP) connection.
 7. Acommunication method applied to an access identifier and locationseparation network, comprising: an access service node establishing andstoring, for an accessed terminal, a corresponding relationship betweena first identifier and a second identifier of the terminal, and abinding relationship between the first identifier and atransmitting-receiving link; and when receiving a data message whosedestination address is the first identifier of the terminal, the accessservice node converting the first identifier to the second identifieraccording to the corresponding relationship, and forwarding theconverted data message to the terminal through thetransmitting-receiving link corresponding to the first identifieraccording to the binding relationship.
 8. The method according to claim7, wherein, the first identifier is an access identifier of theterminal, and the second identifier is a private network IP address ofthe terminal.
 9. The method according to claim 8, wherein, the accessidentifier of the terminal is composed of the private network IP addressof the terminal and prefix/suffix information, and the prefix/suffixinformation is a constant or variable determined based on the accessidentifier and location separation network, and/or, the accessidentifier of the terminal adopts an address coding format of IPV6. 10.The method according to claim 7, wherein, the transmitting-receivinglink refers to a point-to-point connection relationship established bythe access service node for the terminal, and the point-to-pointconnection relationship is a General Packet Radio Service TunnelingProtocol (GTP) connection or a point-to-point protocol (PPP) connection.11. A communication method applied to an access identifier and locationseparation architecture network, comprising: when an access service nodeto which a terminal accesses receives a data message sent from acorrespondent node to the terminal, the access service node distributinga connection identifier to the correspondent node of the terminalaccording to an access identifier of the correspondent node in a sourceaddress of the data message, and storing a corresponding relationshipbetween the connection identifier and the access identifier of thecorrespondent node; and when the terminal communicates with thecorrespondent node through the connection identifier, the access servicenode to which the terminal accesses obtaining the access identifier ofthe correspondent node according to the corresponding relationship todetermine the correspondent node, and realizing conversion between theaccess identifier of the correspondent node and the connectionidentifier.
 12. The method according to claim 11, wherein, theconnection identifier is a public network address or a private networkaddress in a traditional communication network.
 13. The method accordingto claim 11, the method further comprising: the access service nodedistributing the same or different connection identifiers to thecorrespondent nodes of different accessed terminals.
 14. A communicationmethod used for realizing intercommunication between an accessidentifier and location separation network and a legacy IP network,comprising: when receiving a data message sent from the accessidentifier and location separation network to the legacy IP network, anintercommunication node converting a first identifier of the datamessage to a corresponding second identifier and then sending the datamessage to the legacy IP network; when receiving a data message sentfrom the legacy IP network to the access identifier and locationseparation network, the intercommunication node converting the secondidentifier in the data message to the corresponding first identifier andthen sending the data message to the access identifier and locationseparation network.
 15. The method according to claim 14, wherein, thefirst identifier is an access identifier of a terminal in the accessidentifier and location separation network and is composed of a privatenetwork IP address of the terminal and prefix/suffix information; thesecond identifier is a public network IP address.
 16. A communicationmethod used for realizing intercommunication between an accessidentifier and location separation network and a legacy IP network,comprising: when a first terminal in the legacy IP network communicateswith a second terminal in the access identifier and location separationnetwork, an intercommunication node distributing to the second terminala connection identifier identifiable to the first terminal and storing acorresponding relationship between the connection identifier and anaccess identifier of the second terminal, and when the first terminalcommunicates with the second terminal through the connection identifier,the intercommunication node obtaining the access identifier of thesecond terminal according to the corresponding relationship to determinethe second terminal and realizing conversion between the accessidentifier and the connection identifier of the second terminal.
 17. Themethod according to claim 16, wherein, the connection identifier is apublic network IP address or a private network IP address in the legacyIP network.
 18. The method according to claim 16, wherein, theintercommunication node distributes the same or different connectionidentifiers to the second terminals communicating with different firstterminals.
 19. A method for forwarding a data message during acommunication process applied to an access identifier and locationseparation network, comprising: when an access service node to which aterminal accesses receives a data message sent from a correspondent nodeto the terminal, the access service node distributing a connectionidentifier to the correspondent node according to an access identifierof the correspondent node in a source address of the data message, andstoring a corresponding relationship between the connection identifierand the access identifier of the correspondent node; the access servicenode to which the terminal accesses replacing the source address in thedata message with the connection identifier and then sending the datamessage to the terminal; after receiving the data message in which thesource address is the connection identifier, the terminal responding tothe correspondent node with a data message using the connectionidentifier as a destination address; after receiving the data messagewith which the terminal responds, the access service node to which theterminal accesses searching for the stored corresponding relationshipaccording to the connection identifier to obtain the access identifierof the correspondent node, and replacing the destination address in thedata message with the access identifier of the correspondent node andthen forwarding the data message to an access node to which thecorrespondent node accesses.
 20. A method for forwarding a data messageduring a communication process applied to an access identifier andlocation separation network, comprising: an access service node to whicha terminal accesses establishing a point-to-point connectionrelationship for the terminal, and storing a binding relationshipbetween the point-to-point connection relationship and an accessidentifier of the terminal; when the terminal sends a data message to acorrespondent node through the point-to-point connection relationship,the access service node to which the terminal accesses replacing asource address in the data message with the access identifier of theterminal according to the binding relationship, and then sending thedata messa_(g)e to an access service node where the correspondent nodeis located; after receiving the data message, the access service nodewhere the correspondent node is located distributing a connectionidentifier to the terminal according to the access identifier of theterminal therein, and storing a corresponding relationship between theconnection identifier and the access identifier of the terminal; thenreplacing the source address in the data message with the connectionidentifier and then sending the data message to the correspondent node;and the correspondent node responding with a data message using theconnection identifier as a destination address, and the access servicenode where the correspondent node is located replacing the destinationaddress in the data message with the access identifier of the terminalaccording to the stored corresponding relationship and then sending thedata message to the access service node where the terminal is located.21. The method according to claim 20, wherein, the access identifiercomprises a private network IP address part in a traditionalcommunication network, and prefix/suffix information; the prefix/suffixinformation is a constant or variable determined based on the accessidentifier and location separation network; and/or, the accessidentifier adopts an address coding format of IPV6.
 22. The methodaccording to claim 20, wherein, the connection identifier is a publicnetwork IP address or a private network IP address in the traditionalcommunication network.
 23. The method according to claim 20, wherein,the access service node distributes the same or different connectionidentifiers to the correspondent nodes of different accessed terminals.24. A communication method applied to an access identifier and locationseparation network, comprising: a first access service node establishinga first point-to-point connection relationship and a secondpoint-to-point connection relationship respectively for a first terminaland a second terminal that have accessed, and storing bindingrelationships between the point-to-point connection relationships andaccess identifiers of corresponding terminals respectively; whenreceiving a data message using the access identifier of the firstterminal as a destination address, the first access service nodedistributing a first connection identifier to an correspondent node ofthe first terminal according to the access identifier of thecorrespondent node in a source address in the data message, and storinga corresponding relationship between the first connection identifier andthe access identifier of the correspondent node; and when receiving adata message using the access identifier of the second terminal as adestination address, the first access service node distributing a secondconnection identifier to an correspondent node of the second terminalaccording to the access identifier of the correspondent node in a sourceaddress in the data message, and storing a corresponding relationshipbetween the second connection identifier and the access identifier ofthe correspondent node; wherein, the second connection identifier is thesame as or different from the first connection identifier.
 25. Acommunication node applied to an access identifier and locationseparation network, comprising an access unit and a message forwardingunit, wherein, the access unit is configured to establish, for eachaccessed terminal, a binding relationship between a first identifier ofthe terminal and a transmitting-receiving link; the message forwardingunit is configured to, when receiving a data message sent from theterminal on the transmitting-receiving link, if a source address of thedata message is a second identifier of the terminal, convert the sourceaddress to the first identifier of the terminal according to the bindingrelationship and then send the data message to a backbone network forforwarding; and, when receiving a data message whose destination addressis the first identifier of the terminal, convert the first identifier tothe second identifier, and forward the converted data message to theterminal through the transmitting-receiving link corresponding to thefirst identifier according to the binding relationship.
 26. Thecommunication node according to claim 25, wherein, the first identifieris an access identifier of the terminal, and the second identifier is aprivate network IP address of the terminal, and the access identifier ofthe terminal is composed of the private network IP address of theterminal, and prefix/suffix information; the message forwarding unit isconfigured to implement conversion between the first identifier and thesecond identifier by removing or adding the prefix/suffix information.27. A communication node applied to an access identifier and locationseparation network, comprising a connection identifier distributing unitand an address converting unit, wherein, the connection identifierdistributing unit is configured to, when receiving a data message sentfrom an correspondent node to a terminal, distribute a connectionidentifier to the correspondent node of the terminal according to anaccess identifier of the correspondent node in a source address of thedata message, and store a corresponding relationship between theconnection identifier and the access identifier of the correspondentnode; the address converting unit is configured to replace the sourceaddress in the data message sent to the terminal with the connectionidentifier according to the corresponding relationship and then send thedata message to the terminal; and, after receiving the data messageusing the connection identifier as a destination address from theterminal, replace the destination address in the data message with theaccess identifier of the correspondent node according to thecorresponding relationship and then forward the data message to thecorrespondent node.
 28. The communication node according to claim 27,wherein, the communication node is an access service node in the accessidentifier and location separation network, or an intercommunicationnode for achieving intercommunication between the access identifier andlocation separation network and a legacy IP network.
 29. Thecommunication node according to claim 27, wherein, the connectionidentifier distributing unit is configured to distribute the same ordifferent connection identifiers to the correspondent nodes of differentterminals.